Industrial processes with non-Newtonian fluids are common in many segments such as petroleum, cosmetic, and food industries. Slurries, emulsions, and gas–liquid dispersions are some examples with industrial relevance. When a fluid flows in a pipe system, pressure losses are always present. For Newtonian fluids, a quite reasonable understanding of this phenomenon was already achieved and is available in the literature. The same cannot be stated for non-Newtonian fluids owing to their complex characteristics, such as pseudoplasticity, viscoplasticity, elasticity, and thixotropy. The understanding of the influence of these characteristics on flow behavior is very important in order to design efficient pipeline systems. The design of such systems requires the estimation of the pressure drop due to friction effects. However, there are few works regarding friction losses for non-Newtonian fluids in pipeline systems, making this task a difficult one. In this study, two classes of fluids are investigated and compared with the Newtonian results. The first category of fluids are the ones that exhibits pseudoplastic behavior and can be modeled as a power-law fluid, and the second category are the ones that possesses a yield stress and can be modeled as a Bingham fluid. Polyflow was used to compute the friction losses in both abrupt contractions and expansions laminar flow conditions. It shows that for the expansion cases, the aspect ratio affects more the local friction coefficients than for the contraction cases. The influence of the power index n on local friction losses is similar for both cases, abrupt contractions and abrupt expansions. At low Reynolds numbers, dilatant fluids present the lowest values of the friction coefficient, K, independent of geometry. At high Reynolds numbers, a reversal of the curves occurs, and the dilatant fluid presents larger values of K coefficient. For the cases investigated, there is also a Reynolds number in which all the curves exhibit the same value of K for any value of the power-law index. The effect of shows a different behavior between contractions and expansions. In the case of contractions, the material with the highest dimensionless yield stress has the highest K value. In the case of the expansions, the behavior is the opposite, i.e., the higher the yield stress, the lower is the values of the K coefficient. Equations for each accessory as a function of the rheological parameters of the fluid and the Reynolds number of the flow are also proposed. The data were adjusted according to two main equations: the two Ks method proposed by Hooper (1981, “The Two-K Method Predicts Head Losses in Pipe Fittings,” Chem. Eng., 81, pp. 96–100.) is used for all the contractions cases, and the equation proposed by Oliveira et al. (1997, “A General Correlation for the Local Coefficient in Newtonian Axisymmetric Sudden Expansions,” Int. J. Heat Fluid Flow, 19(6), pp. 655–660.) is used for all the expansions cases. The equations found were compared with the numerical results and showed satisfactory precision and thus can be used for engineering applications.
Skip Nav Destination
Article navigation
February 2017
Research-Article
Friction Coefficients for Bingham and Power-Law Fluids in Abrupt Contractions and Expansions
Sergio L. D. Kfuri,
Sergio L. D. Kfuri
LFTC-PPGEM,
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: skfuri@hotmail.com
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: skfuri@hotmail.com
Search for other works by this author on:
Edson J. Soares,
Edson J. Soares
Professor
LFTC-PPGEM,
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: edson.soares@ufes.br
LFTC-PPGEM,
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: edson.soares@ufes.br
Search for other works by this author on:
Roney L. Thompson,
Roney L. Thompson
Professor
Department of Mechanical Engineering,
COPPE,
Universidade Federal do Rio de Janeiro,
Centro de Tecnologia,
Ilha do Fundão,
Rio de Janeiro 21941-450, Brazil
e-mail: rthompson@mecanica.coppe.ufrj.br
Department of Mechanical Engineering,
COPPE,
Universidade Federal do Rio de Janeiro,
Centro de Tecnologia,
Ilha do Fundão,
Rio de Janeiro 21941-450, Brazil
e-mail: rthompson@mecanica.coppe.ufrj.br
Search for other works by this author on:
Renato N. Siqueira
Renato N. Siqueira
Professor
LPMF-Department Mechanical Engineering,
Instituto Federal de Educação,
Ciência e Tecnologia do Espírito Santo,
São Mateus,
Espírito Santo 29932-540, Brazil
e-mail: renatons@ifes.edu.br
LPMF-Department Mechanical Engineering,
Instituto Federal de Educação,
Ciência e Tecnologia do Espírito Santo,
São Mateus,
Espírito Santo 29932-540, Brazil
e-mail: renatons@ifes.edu.br
Search for other works by this author on:
Sergio L. D. Kfuri
LFTC-PPGEM,
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: skfuri@hotmail.com
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: skfuri@hotmail.com
Edson J. Soares
Professor
LFTC-PPGEM,
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: edson.soares@ufes.br
LFTC-PPGEM,
Department of Mechanical Engineering,
Universidade Federal do Espírito Santo,
Vitória,
Espírito Santo 29075-910, Brazil
e-mail: edson.soares@ufes.br
Roney L. Thompson
Professor
Department of Mechanical Engineering,
COPPE,
Universidade Federal do Rio de Janeiro,
Centro de Tecnologia,
Ilha do Fundão,
Rio de Janeiro 21941-450, Brazil
e-mail: rthompson@mecanica.coppe.ufrj.br
Department of Mechanical Engineering,
COPPE,
Universidade Federal do Rio de Janeiro,
Centro de Tecnologia,
Ilha do Fundão,
Rio de Janeiro 21941-450, Brazil
e-mail: rthompson@mecanica.coppe.ufrj.br
Renato N. Siqueira
Professor
LPMF-Department Mechanical Engineering,
Instituto Federal de Educação,
Ciência e Tecnologia do Espírito Santo,
São Mateus,
Espírito Santo 29932-540, Brazil
e-mail: renatons@ifes.edu.br
LPMF-Department Mechanical Engineering,
Instituto Federal de Educação,
Ciência e Tecnologia do Espírito Santo,
São Mateus,
Espírito Santo 29932-540, Brazil
e-mail: renatons@ifes.edu.br
1Corresponding author.
Contributed by the Fluids Engineering Division of ASME for publication in the JOURNAL OF FLUIDS ENGINEERING. Manuscript received January 12, 2016; final manuscript received July 19, 2016; published online November 3, 2016. Assoc. Editor: Mhamed Boutaous.
J. Fluids Eng. Feb 2017, 139(2): 021203 (8 pages)
Published Online: November 3, 2016
Article history
Received:
January 12, 2016
Revised:
July 19, 2016
Citation
Kfuri, S. L. D., Soares, E. J., Thompson, R. L., and Siqueira, R. N. (November 3, 2016). "Friction Coefficients for Bingham and Power-Law Fluids in Abrupt Contractions and Expansions." ASME. J. Fluids Eng. February 2017; 139(2): 021203. https://doi.org/10.1115/1.4034521
Download citation file:
Get Email Alerts
Entrance Lengths for Fully Developed Laminar Flow in Eccentric Annulus
J. Fluids Eng (May 2025)
Switching Events of Wakes Shed From Two Short Flapping Side-by-Side Cylinders
J. Fluids Eng (May 2025)
Related Articles
Developing Region Solution for High Reynolds Number Laminar Flows of Pseudoplastic and Dilatant Fluids in Circular Ducts
J. Fluids Eng (April,2017)
Pressure-Loss Coefficient of 90 deg Sharp-Angled Miter Elbows
J. Fluids Eng (June,2018)
Turbulent Drag Reduction by Biopolymers in Large Scale Pipes
J. Fluids Eng (April,2015)
Drag Reducing Flows by Polymer Solutions in Annular Spaces
J. Fluids Eng (May,2018)
Related Proceedings Papers
Related Chapters
Hydraulic Resistance
Heat Transfer & Hydraulic Resistance at Supercritical Pressures in Power Engineering Applications
Heat Generated in Pipe Flows Due to Friction
Everyday Heat Transfer Problems: Sensitivities to Governing Variables
A Collection of Handy Hydraulic Formulas Based on an Industry-Standard Reference for Pressure Drop Calculations, Incompressible Fluid Flow in Piping and Ducts—Crane Technical Paper No. 410
Hydraulics, Pipe Flow, Industrial HVAC & Utility Systems: Mister Mech Mentor, Vol. 1